Automatic foundry molding machine



June 8, 1954 5. J. GEDRIS AUTOMATIC FOUNDRY MOLDING MACHINE 6 Sheets-Sheet 1 Filed Dec. 26, 1952 5 i r fi 32 mm. m m2 mi 91 m /n van for Sfan/ey James Georis 2 al/m June 8, 1954 s. J. GEDRIS AUTOMATIC FOUNDRY MOLDING MACHINE 6 Sheets-Sheet 2 Filed Dec. 26, 1952 /n ven for James Geo June 8, 1954 5. J. GEDRIS 2,680,270

AUTOMATIC FOUNDRY MOLDING MACHINE Filed D80. 26, 1952 I 6 Sheets-Sheet 3 /n Pen for Sfan/ey James Georlls Affbrney June 8, 1954 s. J. seams AUTOMATIC FOUNDRY MOLDING MACHINE Filed Dec. 26, 1952 6 Sheets-Sheet 4 IZOu lnven for n/ey James Geon's J Affrne June 8, 1954 5. J. GEDRIS AUTOMATIC FOUNDRY MOLDING MACHINE 6 Sheets-Sheet 5 Filed Dec. 26, 1952 /n venfor. s Geor/s June 8, 1954 S. J. GEDRIS AUTOMATIC FOUNDRY MOLDING MACHINE Filed Dec. 26, 1952 6 Sheets-Sheet 6 O U 0 m N 9 O Q N v Q I: U m 2' I q O I 2 5 o g i: v u E g r g 7 3 f? '0 NE 3 g I") 5 m F) a, Q o /cl jrg m g Chg 5 3 d V K m x VF q- 3 Q I 5 w P f m i h E #j m E 9 =Lf:1 1 v m 5? m 5 Q R 2 0 8 Q m 5 0 F g 2) g 3 m I $1 /nv Q QL Q Sfan/ey James (fed/vs A iqmz Patented June 8, 1954 UNITED s'rArss rATENT OFFICE 3 Claims.

This application relates to foundry equipment, and more particularly to an entirely automatic machine capable of making an entire mold without the intervention of an operator and to the process cycle of making a mold which I have developed, the carrying out of which may be accomplished by my machine.

This application is related to my application entitled Molding Machine, Serial No. 723,025, filed January 20, 1947, now abandoned.

Although the art of casting metals is ancient, antedating most civilizations still existent, it still today remains a largely manual industry. Al though the forming of metals other than by casting has become, to a very large extent, an automatic procedure carried out by large, complex and highly accurate machines, the making of'molds for castings remains a hand operation. Many simple and complex machines have been developed for use in the making of molds. These machines, however, have not been automatic. They are merely mechanical adjutants to a primarily manual operation. The number of manual operations and their particular relationship one to the other remains much the same as it was more than a century ago. No one of these prior developments attempts to reduce the making of a complete mold to an integrated cycle consisting of a comparatively small number of precisely timed and coordinated steps. These previous developments have not only not attempted to reduce the making of a complete mold to a timed and coordinated cycle but they have not attempted to divide this cycle into subcycles whereby the various steps involved in making a mold may be carried out simultaneously to reduce the production time necessary to produce a given number of molds.

None of the previous inventions provides a machine capable of taking a pair of empty flasks at one end of the machine and of turning out a complete mold ready for pouring of the molten metal at the other end without the intervention of an operator. All of theprevious machines at some point utilize an operator to carry out at least one, usually a large number, of the steps necessary to make the completed mold. It is recognized that in the making of a mold there are many variables which must be overcome. It is because of these variables that the intervention of an operator has always been believed to be essential. My machine provides a mechanism capable of making a mold either despite these variables or by eliminating these variables, thus making the presence of the operators entirely unnecessary.

It is, therefore, a primary object of my invention to provide a new cyclic process for making a complete mold which consists of at least two subcycles which may be carried out substantially simultaneously.

It isa further object of my invention to provide a fully automatic mold making machine capable of making a'completed mold ready for casting without the intervention of an operator.

It is an additional object of my invention to provide a fully automatic molding machine which is relatively simple to construct and which may be entirely confined within a relatively small area.

It is a further additional object of my invention to provide a fully. automatic-mold making machine which is adapted for operating under the conditions of abrasion and corrosionnormally found in the conventional foundry.

These and other objects of my invention will be immediately seen by those acquanted with the design, construction and use of foundry equipment upon reading the following specification and the accompanying drawings.

In the drawings:

Figure 1 is a sectional plan View of my automatic molding machine taken along the plane 1-! of Figure 2.

Figure 2 is a broken, sectional, elevation view of my automatic-molding machine taken along the plane IIII of Figure 1.

Figure 3 Ba sectional, side elevation view of the cope mold making portion of my automatic molding machine taken along the plane III-III of Figure 1.

Figure 4 is a fragmentary, plan, sectional view taken along theplane IV-IV of Figure 2.

Figure-5 is a sectional, elevation view taken along the plane IIII of Figure 1 but showing only the cope mold making station and showing the flask in raised position.

Figure. 6 is a side elevation View of the lower portion of the cope mold making station showing the flask in raised position.

Figure 7 isan oblique view of the secondary strike off for my automatic molding machine.

Figure 8 is a broken plan view of thesand hoppers for my automatic molding machine showing the'means for measuring the sand in the hoppers.

Figure 9 is abroken. fragmentary, side elevation viewof my sand hoppers showing the means 7 for releasing the sand from the sand hoppers but not showingany of thestructure for measuring the sand the. hoppers.

Figure 10, is a fragmentary side elevation view of the turnover frame for my automatic molding machine.

Figure 11 is a fragmentary, end elevation view of the cope flask hoist for my automatic molding machine.

Figure 12 is an enlarged fragmentary view of the switch track for my cope flask hoist mechamsm.

Figure 13 is a somewhat schematic representation of the control mechanism for coordinating the various operations of my automatic molding machine.

Figure 14 is a diagrammatic sketch of the valves and cylinders for controlling and actuating the various parts of my automatic molding machine.

Figure 15 is a fragmentary oblique view of the liquid parting applying mechanism for my automatic molding machine.

In executing the objects and purposes of my invention, I have provided a molding machine consisting of a pair of parallel conveyors each terminating in a third conveyor positioned perpendicularly to these conveyors. one of the pair of conveyors I have provided a mold making station. One of these mold making stations is designed to make the drag mold and the other is designed to make the cope mold. The operation of the stations is coordinated whereby each step carried out at one mold making station is simultaneously carried out at the other mold making station. Thus, when a single mold making cycle is completed at one mold making station, it is also completed at the other mold making station. The molds completed in these mold making stations are moved onto the third conveyor where the drag mold is inverted and mated with a cope mold to form a complete mold ready for pouring.

In the following description the terms upwardly and downwardly are freely used and are to be taken as upwardly as the machine is normally used and as shown in Fig. 2 and downwardly away therefrom. The terms forwardly" and rearwardly are frequently used in relation to the conveyors supplying flasks to both the cope mold making station and the drag mold making station. As so used, the term forwardly is to be taken as meaning in the direction in which the empty flasks move along these conveyors through the mold making stations and onto the third conveyor where the flasks with a mold formed within them are joined together to form a completed mold, and the term rearwardly away therefrom. The terms upstream and "downstream are also freely used in describing the conveyor between the mold making stations. As so used the term downstream is to be taken as meaning in a direction away from the drag mold making station and toward the cope mold making station and upstream away therefrom.

Referring now to the drawings in greater de tail, the numeral I indicates a drag mold making station operatively connected to a cope mold making station 2 by a step by step conveyor 3. Flasks 4 are supplied to the drag mold making station I by a step by step conveyor 5. Flasks 6 are supplied to the cope mold making station 2 by a step by step conveyor 1. The flasks 4 and 6 are identical in size and shape. Each of the flasks 4 and 3 is equipped with an outwardly extending ear 8 on each side at its rearward end, as the flasks are seated on the conveyors 5 and I. The upper end of each of the ears. 8 is D Q Within each a substantial distance from the upper rim of the flask as the flask is situated on these conveyors.

Cope and drag flask conveyors The conveyors 5 and I are identical in construction and operation. Therefore, I shall describe the conveyor 1 for the cope flasks, it being understood that this description applies equally to the conveyor 5 for the drag flasks. The numbers for like parts on each conveyor will be identical except that the numbers appearing on the drag flask conveyor 5 will be suflfixed by the letter a.

The conveyor I includes a pair of spaced rails I (Fig. 1) constituting an outer track II and a pair of spaced rails I2 constituting an inner track I3 centered between and above the rails Ill. Mounted on the outer track II by means of the wheels I5 is the carriage IS. The carriage I6 consists of a pair of side members I! held together by the U-shaped braces I8 and are spaced apart sufficiently to receive a flask 6 therebetween. At the forward end of the carriage are a pair of lugs I9. The lugs 19 are each directed toward each other whereby they will contact the ears 8 on the flask 4. A pair of clips 20 are pivotally mounted to the side members I? of the carriage I6 adjacent its rearward end. Each of these clips 20 is urged toward the flask E by a spring 2!. Pivotal movement of each of the clips 23 toward the flask 4 is limited by a peg 22 cooperating with a cutout in the rearward end of the clip. Each of the clips 20 is provided with a slot 23 adjacent its forward end for receiving one of the ears 8.

The lower edge of each of the side members I! of the carriage I6 is formed into teeth for engaging a gear 3| mounted on the shaft 32 (Fig. 3). One gear 3I is provided for each of the side members ll. The shaft 32 extends between and under both the cope flask conveyor I and the drag flask conveyor 5. Between these conveyors a gear 33 is mounted on the shaft 32 for engaging the rack 34. The rack 34 is supported by the roller 35 (Fig. 3) and actuated by means of the cylinder 36 and piston 31'. Reciprocation of the piston 31 causes simultaneous, opposite reciprocation of the carriages on both the cope flask conveyor I and the drag flask conveyor 5.

Cope and drag mold making stations The cope mold making station 2 and the drag mold making station I are identical in construction and operation. These mold making stations have identical parts except those parts which are common to both mold making stations. Therefore, I shall describe the cope mold making station 2, it being understood that the structure described is duplicated at the drag mold making station I, except where the parts are stated to be common to both mold making stations. The numbers for like parts at each mold making station, but which parts are not common to both mold making stations, will be identical except that the numbers appearing on the drag mold making station I will be suflixed by the letter a.

Surrounding the mold making station are four vertical standards 40 (Fig. 1) having longitudinal capping beams M (Fig. 2) and lateral capping beams 42. The longitudinal capping beams M extend between the cope mold making station 2 and the drag mold making station I and are common to both stations. A pair of outlying vertical standards 43 (Fig. 2) are provided for supporting the ends of the longitudinal capping beams 4|.

aosop'zo The =lower-part of the cope -mold making station '2 consists of a-pedestal 50 including-a pair of spaced, vertical guides 5 I. Slidably mounted "in each of the guides "ii is a slide 52, each of which supports -a rail-section 53. The rail sec- .tions 53 are spaced apart the sameldistance as the rails I2 of the inner track 13. The slides '52 are'each attached to oneend of a. toggle unit 5d. The other end of each of the toggle units is attached to a shaft .55 rotatably ,journaled in the ears 500a. secured to the fixed guides 5i and 51a. "The shaft 55 is common toboth of the molding :stations, whereby rotation .of the shaft in one direction will cause the toggl units 54 atoopen, :raising the slides 52 and rail sections 53 (Fig. .6). Rotation of the shaft v55 in itheother direction will close :the toggle units 5,"lowering the slides 52 andrails 53 (Fig. 3). "Thus, the raising and lowering of the rails :53 in both the cope mold :making station .2 and the drag .mold making station l is effected simultaneously. -The rotation of the shaft is effected by the cylinder -56 :and piston 5i acting through the link 58 :secure'd on one of its ends to the shaft 55 and on :the other of its ends to the piston :1. The cylinder 53 is pivotally sup-ported by the standard .759. A single cylinder 56 rotates the shaft -55.

Between the rails 53 is .a pattern plate 68 seated on the platform 61. The platform 6| is supported by the vertical cylinder 62 acting through the piston 63 (Fig. 5). The fiaskst are :positioned on the pattern plate '58 by a pair of guide pins 6 4 (Fig. 5) mounted on the pattern plate 59. The guide pins (is enter suitable holes in the flasks E. The purpose and operation of the cylinder 62 will be explained under Opera- Above the cop molding station 2 and the drag molding station 5 a pair of guide wheels 13 (Figs. 2 and 3) are mounted on each of the vertical standards 46, ite, and the outlying vertical standards 43 and its. The guide wheels Til of each pair are vertically spaced apart to receive a beam ii therebetween. One of the beams H is mounted at the forward end and one at the rearward end of the mold making station. The beams 'H are common to both the cope mold --making station 2 and the drag mold making station 5. lounted on and between the beams H by means of the hooks "i2 loosely seated in the U-shaped yokes 89 are a pair of secondary strike off-frames i3 and its (Fig. '7). The combinations of the hooks l2 and yokes '39 permit the strike off to move vertically relative to the beams ll but permit no horizontal displacement. The secondary striire oil frames '53 and 1.3:: are spaced apart the same distance as the spacing between the mold making stations.

Above and spaced from the guide wheels it are additional pairs of guide wheels .34. The disposition, spacing and number of the guide wheels I is identical to that of-the guide wheels "it. Mounted between the guide wheels 14, on both the forward and rearward ends of the molding stations, is a beam iii. The beams '15 are identical and parallel to the beams "H and by means of the hangers it support a pair of primary strike cifs is and Na spaced apart the same distance as the spacing between the mold making stations. At the leading edge of the secondary strike offs E3 and 73a (Figs. 2 and 15) there is mounted a liquid parting sprayer t5 and 65a, respectively. The liquid parting sprayer consists ofan air pipe 56 having a plurality of -vertically directed orifices "61. Below and ad- *between the tracks -bear upon the lower ones of :the tracks 36 and 'jacent *the air :pi-pe :66 is .a liquid parting lpi'pe es having a plurality of horizontally directed :nozzles $69. 'T-he nozzles 559 are ach vertically aligned with one :of the orifices E1. 'The flow of air through the air pipe .65 is controlled by :the -valve 2 1-0. "The construction and operation of the -liquid :parting sprayers is disclosed in my icopending application entitled Means .for Applying Liquid Parting, Serial *No. 142,257, filed -=l\-/laroh '3, 1950, now abandoned.

The beams :H are, at their ends adjacent the drag mold making station 1, connected by the rod 18 which, in turn, is pivotally mounted to :oneendqof the hinged arm '19. The other-endof :th-e hinged arm 1'9 is pivotally mounted to the stationary plate-'80 supported on the bearnmemher '8'! extending between the outlying vertical standards 43a. Adjacent the stationary plate "80, the hinged arm is connected to the piston 82 actuated by the cylinder 83.

The beams 15 are, at their ends adjacent the drag mold :malring station 1, connected by the rod M, which rod is pivotally mounted to one end of :the hinged arm 85. The other :end of the hinged arm 85 ,is pivotally mounted to the stationary plate es. Adjacent the stationary plate 189, the -hinged arm 35 isconnected to the piston 86 actuated by the cylinder 31. Thus, movement of the piston '82 will impart similar movement z-to bot-her" thebeams "H and the sec- 'ondar-y strike offs "73 and i3a. Likewise, movement of thepiston =86 will impart similar movementito both of the beams "E5 and the primary str'ikeioifs Ti and ila.

Substantiallyabove the beams t5 and parallel to them are tracks 't'iLcommon to both the cope mold making station-2 and the drag mold makingstation i. The tracks 9t are mounted in-vertically spaced pairs one pair on theforward end and one on the-rearward end of themold making stations. The tracks '98 are each mounted to the-verticalstandards and Ma andthe -outlying vertical standards ith and 1230, and are spaced therefrom byspacers 9'! (Fig. 3). The

cradle '92, consisting of'a .pair of runnersifit and cross beams 94, 'is mounted to the tracks iii) by means of the wheels "25. The wheels 35 {travel Normally the wheels have a slight clearance with the upper of the tracks '95.

distance-as the spacingbetween the mold :mak-

ing stations.

Adjacent each of the sand'guidesydfi and 36a is a tamperhead 1'80 and vHlila, respectively. The

tamper hea'ds 1 30 and Nita are each supported by a frame 10! and Etta, respectively,-mounted -onthe carriage 92. Theframes It! and llilaare identical. Therefore, I shall descrihethe frame 40! 'for the tamper head li'li) at the cope .mold

-making-station 2 only. "It will be remembered,

however, that the identical parts areduplicated 'atthe drag mold making station'l and will be indicatedby the same numerals, exceptthose parts appearing at the drag mold making station .will

--be-suffixed' by the letter a.

The frame NH consists :of .a :pair vor" 2 Uashaped supports I02 each mounted to one of the runners 93 of the cradle 92. Each of the U-shaped supports I02 includes a pair of vertical, parallel way bars I03 free at their lower ends and joined at their upper ends by the end bar I04. The way bars I03, substantially midway between their free ends and the end bar I04, are each rigidly attached to one of the runners 93. Between the end bars I04 of the pair of U-shaped supports I02 extends a terminal bar I05 from the midpoint of which depends the cylinder I06. The tamper head I is suspended, by means of the yoke I01, from the piston I08 of the cylinder I06. The yoke IN is attached to the peripheral frame I09 of the tamper head I00. On each side of the yoke 01 is a pair of slide blocks IIO. A pair of slide blocks I it! is provided for each of the way bars I03, which way bars are slidably received between the slide blocks IIO. Thus, four pairs of slide blocks Iiii are provided on each of the tamper heads.

The tamper heads I00 and IBM are spaced apart the same distance as the spacing between the cope mold making station 2 and the drag mold making station i. The tamper heads I00 and Hitler each consist of a peripheral frame I09 containing a plurality of heavy, vertical weights or bars IIi each free for vertical reciprocating movement with respect to the frame I09. The exact construction of the tamper head is not further detailed because the details of its design form no part of this invention and are fully disclosed in my Patent No. 2,325,501.

The spacing between the sand guides 98 and 95a and the tamper heads I00 and I00a, respectively, is such that when the sand guides 96 and 96a, are vertically aligned with the pattern plates 60 and 68a, respectively, the tamper heads I00 and I00a. are entirely removed from above these pattern plates. The purpose and importance of this construction will appear more fully hereinafter. The alignment and removalof the sand hoppers 90 and 96a and the tamper heads I00 and I000! is effected by reciprocation of the cradle 02. The cradle 92 is reciprocated by the cylinder H through the piston H6. The cylinder is mounted on the lateral beam I I1.

Vertically aligned with each of the pattern plates 60 and 60a is a sand hopper I20 and I20a, respectively. The sand hoppers I20 and I20a are stationary and rigidly mounted to the longitudinal capping beams 4!. Each of the sand hoppers is equipped with lower vanes, each vane mounted on one of the rotatable shafts I2I. The rotatable shafts IZI are each provided with an arm I22 on one end (Fig. 9), which arms are each joined to the link I23. The link is reciprocated by the cylinder I24 and piston I25 through the tie bar 534. The cylinder I24 is mounted to the lower face of one of the lateral capping beams 42.

Spaced substantially above the vanes are a plurality of closely spaced rods I26 (Figs. 2 and 8) extending through the hopper longitudinally of my molding machine. The rods I25 are joined together by the head piece I21. The head pieces I21 and IZia are joined for simultaneous operation by the tie rods I28. The piston I29 of the cylinder I30 is attached to the head piece I2'Ia. The cylinder I30 is mounted on the vertically adjustable pedestal I3I. The sides of the sand hoppers I20 and I200: are each formed of two telescoping sections, the upper section of which is vertically adjustable with respect to the lower section by means of the slots I32 and wing nuts Lil) Further and more detailed description of the sand hoppers is not considered to be necessary inasmuch as they may be constructed in several ways without affecting the principle of my invention. A description of a preferred construction for my sand hoppers is to be found in my application entitled Molding Machine, Serial No. 732,047, filed March 3, 1947, now Patent 2,542,243 issued February 20, 1951.

Drag flask inverter At the forward end of the rail sections 5311 of the drag mold making station I and overlying the conveyor 3 are a pair of stationary rails I40. The rails I are spaced apart the same distance as the rail sections 53a and are at the same elevation as the rails I2a and the rail sections 53a 7 when the latter are in their raised position. On the downstream side of the rails I40 is a shaft I4I rotatably journaled to the conveyor side beams I42. Below the shaft I4I and between the side beams I42 are the spaced tracks I43 for conveying the drag flasks 4 to a position adjacent the cope mold making station 2. To the shaft MI by means of the hanger straps I55 is attached the turnover frame I44. The turnover frame I44 (Figs. 1 and 10) includes a pair of spaced arms I45 each pivotally mounted at one of its endsto one of the sides I48 of the turnover frame adjacent the shaft I4I. The arms I45 are joined together at their ends remote from the shaft MI by the cylinder 47 and piston I48. Each of the arms I45 pivotally mounts a pair of fingers I49, which fingers are adapted to grip the rim of a drag flask 4. The fingers are guided by the guide blocks I50. The shaft MI is rotated by means of the gear I5I which meshes with the rack I52. The rack is actuated by the cylinder I53 and piston I54.

The length of the hanger straps IE5 is such that when the turnover frame M4 is pivoted to a position above and parallel to the rails I40, the fingers I49 may grip the bottom rim of a drag flask 4, and, when the drag flask 4 has been pivoted to a position at which it seats upon the spaced tracks I43, the fingers 649 are spaced from the tracks I43 the height of the drag flask 4. The shaft MI is rotated 180 and in so doing transfers the drag flask 4 from the rails 48 to the tracks I43 and inverts the flask. A description of a preferred construction for my flask inverter is to be found in my application entitled Flask Turnover for Foundry Molding Machine, Serial No. 176,508, filed July 28, 1950, now Patent 2,627,335 issued February 3, 1953.

Conueyor between mold making stations The conveyor 3 consists of the spaced tracks I43. Beneath and between the spaced tracks I43 are a pair of reciprocating rods Hi0 slidably mounted on the laterals I$I. The rods I60 are joined, adjacent the drag mold making station I, by the bar E2. The bar N22 is operatively attached to the piston I53 of the cylinder I64. The rods I60 mount pivoted dogs 55. The dogs 165 are mounted in pairs, each pair of which will engage the upstream end of a flask and move it downstream of the conveyor with the rod I60. The dogs IE5 are spaced along the rods H in such a manner that a first pair of them will engage a flask deposited by the turnover frame I44 and push the flask downstream to a point where on the next actuation of the rods I that flask will be pushed by a second pair of dogs to a position ready to receive the cope flask 8. Additional units Cope flask hoist- The cope flask. elevator orhoisti 1.1a is; situated above the conveyors; inv alignment with the cone mold making station 2. and at theerearwardaenct of, the conveyor 'i'. The supporting frame: for the.

flask elevator or hoist lit]; includes the. vertical. standards i ii positioned on. each sideotv the. con-- veyor 3. (Fig. 1). Thevertical standards, are.- joined' by the top beams H2. intermediate beams.- l-13; and lower beams l'i-t, each extending later ally'of the conveyor 3. The toplbeams I372. mount. the. cap'beam H from which depends. the cylin der l'lfifjor actuating the piston til. Mounted on the piston illie therod Nil-extendinglaterally, oithe conveyor 3. On each endof tha rod [18 is. a terminal bar I19, centered about therod Ila. At, each end of the terminal bar an arm. L813- is pivotally mounted adjacent the upper endoii. the. arms; Thus, there is a pair of arms; will, on-each side of. the rod 118. The arm constituting each pair are joined by a. brace ml. and an L.-shaped. angle i813. Each of the angles lll ichasasubstam tially horizontal leg I83, which. legs are directed; toward each other.

Thearms fit-project ashort distance abovethe terminal bars ill). The pair of arms l8t .mounte,d-' on each of the terminal barsare: are joined by a spring we whereby the lowerend'of: each pain i arms are forcedapart.v The rod.,ll8,-,terminal, bars lid, arms 58%;, braces 58!; and angles. L82: together form the reciprocating. clasp assembly ofthe hoist.

Mounted on. and extending outwardl from eachof the braces it! area pair. of guide rollers 1'85. Each of the guide, rollers lliE-bears against. one of the guides ills. Each of the guides. com sistsof a main track i87 having a lower portion 253 oiiset outwardly away from the 13.0.. A. switch track i852 is pivotally mounted inwardly.

oithe lower portion ifisand is normally vertically c ligned with: the upper portionof. themain track. Each main track it? and switch. track 4.8.9. is mounted on a beam E95. switch track 39 includes a pivot pin. (-9 and a peg E's-2 extending through. the. slot I93 in. the beam ice. A spring its, bearing againstthepeg H 2, urges the switch track its into. alignment with the upper portion of the main track. 1.81. The lower end of the lower portion. 188 of the main track depends substantially below the switch track 289.

More detailed description of my flash hoist is not believed necessary to a proper understanding of my mold making machine. A description. of a preferred embodiment oi: my cope flask hoist. is to. be found in my application entitled Flask Hoist for Foundry lvleldirr Mac ine, Serial No. 176,507, new Patent 2,615,558 issued October 28, 1952. V

The various actuating cylinders utilized. for driving the various operative elements of my. automatic mold making machine constitute collectively a power means. This collective term. is used inasmuch. as it. is to. beaunderstood thatthese cylinders together are but one form of mechani- The mountingv for the i cal power by which. my automaticmoldmaking. machine. may. be. driven or. operated.

Q' m on' The. operation of my automatic molding machine constitutes a complete, integrated andfully automatic cycle during: which a complete mold ready for pouring is" formed without the inter-- vention of an operator: Once the operation of the machine is initiated, it is unnecessary-for any operator to intervene either during a completemold' making cycle orbetween each cycle.

It is recognized that auxiliary equipment will be. necessary to supply my automatic molding machine with the necessary flasks; and sandto maintain its operation. Among such equipment will be a source of sand and sand conveyolSto supply the sand hoppers I20 and l20a; It will also be necessary to have a sand conditioner to prepare the sand for my moldmaking machine; However, all ofthis equipmentmay be of standard'constructionand; is well-known to the foundry art. Also necessary will be conveyors-for re- J turning-thejdrag and cope-fiasks iromthe shake out stationsto, the conveyors and}. These-conveyorsmay also be oi conventional construction Since all of this. equipment is of'st-andard, con struction and may be. assembled in anyone of a number of suitable. arrangements, it is not believed necessary to showordescribe it. One such arrangement of this auxiliary equipment is described in. my application entitled Molding Machine, Serial-No. 723,025; filed'January 20, 1 947, now, abandoned.

A drag flask 4 and a cope flask tare simultan'eosuly' deposted on the; drag flask conveyor 5 and cope flask conveyor'lj respectively. Each of; these flasks is so arranged on the conveyor that the lugs 8 are at the rearward" end of the flasks; By means of the cylinder the carriages l 6 and lta'are moved rearwardly. During this rearward movement the clips 20} and 20a, engage-the lugs 83. The cylinder 36 is then actuated in the opposite direction moving the carriages H5- and lilo: forwardly; pushing the flasks: 6 and: 4' with them on the inner tracks? i3 and Mia, respectively. The forwardlimitof travel of the carriages lfi and" lta' is such that when these carriages halt their'for ward movement, the flasks sand 4" are each positioned" on the rail sections 53' and 53a, respectively, with the flasks positioned ready to. be 10W- ered' and seatedfon the pattern plates and tfla;

The cope. flask isaligned by the guide pins 54'. The drag flask is. aligned by the. guide. pins 28;} mounted on the dra flask and entering cooper- 7 ating holes in the pattern plate eta: While the carriages it. and lilo are at thejforward limit of their'travel another flask .6 and another flask v l are deposited on the conveyors-5 respec The carriages l6. and; Mia each dwell at the forward limit of,- their'travel while the cylinder 56 is actuated to simultaneously lower the rail sections 53' and 53a. This. lowering of the rail sec tions. 53 and 53a seats the; flasks 5" and 3' on the pattern plates 63 and Sta, respectively. The flasks. G and 4 are. uided. into, exact r ei's erw th the. pattern. Plates by the uide. pins e l and 2 and, by means. of these guide. pins, are thereafter held. a a nst horizontal" displacement. The lowering. of the. flasks disengages the ears 8 from the clips/2tv and. Ella. After the flasks have been lowered, the. cylinder 3621s actuated to, move. the carriage rearwardly to. engage the flasks. which 11 were deposited on the conveyors and I while the carriages were in their forward position.

During the interval while the flasks G and 4 are being deposited on the rail sections 53 and 53a, respectively, the primary strike oifs l1 and Fla and the secondary strike offs I3 and 13a are each withdrawn to a position to the side of the molding stations I and 2. The cradle 92 is so positioned that the tamper heads I00 and I080. are positioned to the side of the molding stations 2 and I, respectively, and the sand guides 98 and 96a are positioned in vertical alignment between the pattern plates 60 and 60a and sand hoppers I20 and [2%, respectively.

After the carriages I6 and Ifia have been withdrawn to their rearward positions, the primary strike offs I1 and Tia and the secondary strike ofls I3 and 13a are simultaneously moved to a position above and vertically aligned with the flasks 6 and 4, respectively. The secondary strike offs I3 and 13a rest upon their respective associated flasks. While the secondary strike offs I3 and 13a are moving across the pattern plates 66 and 60a, the valve 2H3 is opened to admit air under pressure to the air pipe 66. The air escapes through the orifices S1 and draws liquid parting from the nozzles 69. These air streams atomize the liquid parting and direct it vertically against the pattern plates 60 and 66a. The sup ply of air is terminated when the secondary strike offs l3 and 73a reach the limit of their travel and are positioned over the flasks 6 and 4;

Either while the flasks 6 and 4 are being placed on their respective pattern plates or before, the cylinder I30 is actuated to simultaneously withdraw the rods I26 and I26a from the sand hoppers I20 and I20a. This permits sand placed in the top of the sand hoppers to pass down into the chamber in the sand hoppers between the vanes mounted on the rotatable shafts I2I and I2Ict and the rods I26 and IZEa. The cylinder I38 is then actuated in the opposite direction to force the rods I26 and I261 back through the hoppers I20 and I20a. This entraps a measured quantity of sand between the vanes and the rods I26 and I26a. The actuation of the cylinder I39 is slow so that the inward and outward movement of the rods I26 and I250; is gradual whereby the sand will be caused to cascade into the lower chamber of the sand hopper rather than drop as a lump. This helps to condition the sand immediately prior to its deposit into the flask as is more fully explained in my application entitled Molding Machine, Serial No. 723,025, filed January 20, 1947, now abandoned.

As soon as the primary strike offs I1 and Na and the secondary strike offs i3 and 13a have been positioned above and aligned with the flasks 6 and 4, the cylinder I24 isactuated to rotate the rotatable shafts l2i and lZIa whereby the vanes are moved downwardly into a vertical position, and the sand entrapped inthe chamber above the vanes is released as a mass. This sand falls through the sand guides 96 and 96a and is deposited, as a mass, in the flasks 6 and 4. The sand hoppers I20 and I200. are spaced a very substantial distance above the flasks 6 and 4 whereby the mass of sand, as it strikes the pattern plates 80 and 60a, has an opportunity to develop appreciable momentum. This momentum causes the sand to pack tightly as it is initially deposited. Also, by means of the vanes, the sand is caused to be released from all parts of the sand hoppers 20 and I2Ga whereby the mass of the sand is relatively evenly distributed throughi2 out the area of each of the flasks 6 and 4. As soon as the sand has been released from the sand hoppers I28 and IZilc, the cylinder I24 is actuated in the opposite direction to close the vanes ready for the release of more sand into the chambers above these vanes.

As soon as the sand has been dropped, the cylinder 81 is actuated to withdraw the primary strike ofls I1 and Ila from above the flasks. This levels the sand at the top of the secondary strike offs l3 and 13a. At the same time the cylinder I I5 is actuated to remove the sand guides and 95a from above the flasks 6 and l, respectively, and to align the tamper heads I00 and Nita with these flasks. The cylinders I06 and IIlBa are then actuated to lower the tamper heads I09 and Illfia until the bars or weights III rest entirely upon the sand which has been deposited in the flasks. The cylinders 32 and 620. are actuated in a fashion such that they have a series of short, rapid strokes whereby the flasks 6 and s and the secondary strike offs l3 and 13a are rapidly raised and lowered. During this shaking or jolting process the sand is forced up against the individual weights of the tamper heads [09 and IBM, causing the sand to become densely compacted within the flasks around the pattern on the pattern plate. In this process the compacting results first from the jolting action provided by the cylinders 62 and 62a and secondly from the weight or inertia of the individual weights or bars III. The cooperation between the slide blocks IN and the way bars I03 keeps the tamper heads aligned during the jolting operation. The cooperation between the hooks l2 and the U-shaped yokes 89 permits the secondary strike offs l3 and 53a to move vertically with the flasks during the jolting operation but prevents the secondary strike oils from becoming misaligned with these flasks. When suficient jolting has been provided to securely pack the sand into the flasks 6 and i, the tamping heads me and Iilila are raised by means of the cylinders I06 and Nita, and, by actuation of the cylinder H5, the tamping heads are withdrawn to the side of the molding stations and the sand guides 36 and 95a realigned with the sand hoppers and with the flasks in readiness for the next mold making cycle. At the same time the cylinder 83 is actuated to withdraw the secondary strike ofls l3 and At this point the making of the molds is completed.

The cylinder 5% is now actuated to raise the rail sections 53 and 53a, stripping the flasks and their molds from the pattern plates as and 69a. When the flasks 6 and t have been raised to their upper elevated position, the carriages I5 and Ifia are again moved forwardly on the conveyors l and 5, respectively. As these carriages move forwardly, they bring an empty flask 6 and an empty flask 4 into the molding stations 2 and I. At the same time by means of the lugs I9 and lila, the original flasks, containing the completed molds, are pushed forwardly out of the molding stations 2 and I. The drag flask 4 is pushed onto the rails I l-ll and positioned to be received by the turnover frame M4. The cope flask 6 is pushed into the cope flask hoist I10. While this operation is being carried out, the clasping element is in its raised position whereby the horizontal legs I83 of the angles I82 are positioned above the rails 12 whereby they will seat immediately under the upper rim of the cope flask and support the cope flask as it passes off the ends of the rails l2.

i4 3 the hcist llil.

gamete down around the drag flask 4'. The cylinder I4? is then actuated to draw the arms I45 together, forcing the fingers I l-S about the; lower rim of the drag flask. Actuation of the cylinder I53 then causes the shaft I l'I- to rotate, removing the drag flask i from the rails I40, inverting it and depositing it upon the spaced tracks I43 of the conveyor 3. The cylinder MT is then actuatedto eject the piston :48 separating the arms I45. This releasesthe drag flask. While the drag flask is being inverted, the cylinder we is' actuated to lower the flask hoist whereby'the cope flask 5 will be deposited upon a mating? drag flask t positioned on the spaced tracks [43 immediately below the hoist. It will be understood that several drag flasks are made before making the first cope flask. This is necessary in order to have a drag flask under the cope flask hoist IIO'ready to receive a cope flask. Iii my description I have assumed that several drag flasks have been moved, step by step, down the conveyor 3 to a position where one of them will be ready to receive the dope flask. Once my molding machine has reached this point in its operation, there will always be a drag flask p'ositionedunder the cope flask hoist Ilfl' ready to receive a mating cope flask.

After the drag flask 4 has been deposited on the spaced tracks I43 and the fingers I49 have been caused to release this drag flask, the turnover frame remains stationary until after the next drag flask d has been pushed out of the drag mold making station I onto the rails Hill. The turnover frame Hid is then pivoted to a position where it will clasp the newly positioned drag flask 4. As soon asthe turnover frame EM has cleared the drag flask initially deposited on' the spaced tracks 543, the cylinder its is actuated to force the reciprocating rods IGG downstream of the conveyor 3. By means of the pivoted dogs H55 the drag flask 4 is moved down theconveyor one station. This movement is sufficient to remove the drag flask entirely from the operating area of the turnover frame Md. The drag flask 4 then dwells while the cylinder 9'56 is actuated in the opposite direction to withdraw the rods to their original position ready to receive the next drag flask. The drag flask 4-.positioned on the spaced tracks lit is then positioned midway between the turnover frame While in this position and While stationary any cores which should be added to the mold may be placed in the mold. During the next molding cycle of the machine and after the turnover frame his has placed a second drag flask i on the conveyor, the cylinder I (id is again actuated pushing the first drag flask 8 into position under the hoist lit. There it will remain while the rods i663 return to their initial position. While the drag flask i dwells beneath the hoist, the cope flask E3 is deposited upon it in the manner described above. As the cope flask 6 is deposited upon the drag flask 4, the flasks are aligned by the guide pins 298. It will be seen from this description that my machine is capable of completely automatically making a mold including both the drag mold and the cope mold and of placing these molds together ready for pouring. It is obvious that after the molds have been placed together under the hoist station lit the next actuation of the rods I60 will push the completed mold down- 14 stream on the spaced tracks I43 where theywill' be ready'forp'ouring.

Each of the actuating cylinders is so designed that the maximum length of its stroke is used in the operation of my machine. Thus, it-be comes unnecessary tohave special stops and re-' leases against over travel of any of the parts.-

Operating and coordinating mechanism The'con-trol and timing coordination of all op-' erations in my molding machine is effected" through the control assembly 3% (Figs. 2? and- 3 The means by which I coordinate the operation of each of the: various elements making up my automatic mold making machine is in erfect a: timer; for it times the individual action of each of these elements and functionally unites these. elements into a smoothly operating, unified system. Anything which is used in my automatic mold making machine which effects these same endsand is, therefore, a substitute for the cam, valve and conduit arrangement would also be a timer.

It will be" recognized that my machine may be operatedhydraulically, pneumatically, or electronically. However, for the sake of brevity, I shall describe the control mechanism ior my machine as operated pneumatically. However, it will be understood that pneumatic operation; is merely illustra-tive and that my invention. con.- templates other types of operation and coordina-= tion. It will also beunderstood that the particular new diagram illustrated is only one of many difier'ent-flow patterns which could be employed.

The control assembly Slit consists of a group of valves indicated by the numbers, SIG through 32-3 and 3 Mia through 3 i la and 3 I 941 through 322a. Each of these valves is individually operated by a cam 30!. As many cams SBI are employed as there are valves and all of these cams are mounted on a shaft 362 rotatably supported by the journals 363. At one end of the shaft a chain and sprocket assembly 394 connects the shaft 362 to the speed reducer unit 3%. The speed reducer unit 3% is driven by the electric motor 396, The motor is mounted on the platform 3Q! which is supported on one of the outlying vertical standards ita.

Each'of the cams 3M cooperates with a suit able arm- 369 (Fig. 2) on its associated valve and, by means of the ridge see (Fig. 2 causes the valve to be opened for a predetermined period of time. The cams are eacharranged with their ridges circumferentially located to open their particular valve in timed relationship to the operation of every other valve in such a manner that the entire machine will operate smoothly. I shall now describe the sequence of operationof the valves, it being understood that this sequence covers an entire mold making cycle and is effected by a single 360 rotation of the shaft 302. In the following description the terms forward end of the cylinder and rearward end of the cylinder are freely used and are to be taken as meaning the forward end of the cylinder as being that end adjacent the projecting piston rod and the rearward end of the cylinder as its opposite end. That is, air admitted to the forward end of the cylinder will retract the piston and air admitted to the rearward end of the cylinder will eject the piston.

In describing the cycle of operation of my 15 making stations 2 and I, respectively, and the carriages IE and Mia are in their rearward positions.

The valves 3l3, 3M and 3l5 are each simultaneously opened to admit air through the conduits M3, M4 and M5 to the rearward end of the cylinders 83 and 8'1 and to the forward end of the cylinder II5, respectively. This moves the secondary strike offs I3 and I30. and primary strike offs TI and Ila. into vertical alignment with the pattern plates 65 and 60a. It also moves the cradle 92 to a position wherein the sand guides 96 and 96a are vertically aligned with the pattern plates 65 and 60a. While the secondary strike ofis I3 and 13a are being moved across the pattern plates 66 and 60a, the valve 323is maintained in open position admitting air through the conduit 423 to the valve 2I0. This forces the valve 2I0 to open, causing the liquid parting sprayers E5 and 65a to operate. The valve 323 is closed when the secondary strike offs I3 and 13a are seated over the flasks 6 and 4.

The valve 3H5 is then opened to admit air through the conduit MB to the rearward end of the cylinder I24. This opens the vanes, releasing the sand from the sand hoppers I20 and 120a into the flasks 5 and 4. The valve 3M is then closed and the valve 3I4a opened to admit air through the conduit 4I4a to the forward end of the cylinder 81. This withdraws the primary strike offs I1 and Ila. Simultaneously the valve 315 is closed and the valve 3I5a opened to admit air through the conduit 415a to the rearward end of the cylinder II5. This moves the cradle 92 to remove the sand guides 96 and 96:]. from above the flasks 6 and 4 and to position the tamper heads Hi and Ififia above these flasks, respectively. At the same time the valve 3I5 is closed and the valve 3I6a is opened to admit air through the conduit N60. to the forward end of the cylinder I24 for closing the vanes in the sand hoppers I25 and I2Ila.

The valve 3II is now opened to admit air through the conduit M! to the rearward end of both the cylinders I56 and WM. This lowers the tamper heads Hit and Inca until the blocks I I I rest securely upon the sand deposited in the flasks 6 and 4. When the tamper heads I00 and IDOa have been lowered, the valve 3? is opened to admit air through the conduit M8 to the regulator The regulator 55% admits the air to the rearward end of the cylinders 62 and 62a in a number of short, rapid bursts. This effects the jolting of the sand in the flasks B and 4. The operation continues for several seconds and then the valve 3I8 is closed.

As soon as the valve MS has been closed the valve 3I'I is closed, and the valve 3IIa is opened to admit air through the conduit AIM to the forward end of both the cylinders I06 and Ififia. This raises the tamper heads I00 and IIlIla. As soon as the tamper heads Ill!) and Iflfla are partially raised, the valve 3I3 is closed and the valve 'JI3a opened to admit air through the conduit 4I3a to the forward end of the cylinder 83. This withdraws the secondary strike offs l3 and 13a from above the flasks B and 4.

As soon as the secondary strike ofrs'lii and i311 have completed their withdrawal, the valve (H2 is closed and the valve 322a opened to admit air through the conduit H211 to the rearward end of the cylinder 56. This raises the flasks 6 and 4 from the pattern plates 60 and 60a. The valve 3 is now opened to admit air by means of the 16 conduit 4! I to the forward end of the cylinder 35. This moves the carriages I8 and Ilia forwardly, moving the drag flask 4 onto the rails I40 and the cope flask 6 onto the angles I82 of the flask hoist Fill, and at the same time placing an empty cope flask and an empty drag flask on the molding stations 2 and respectively. Simultaneously the valve 3H3 is opened to admit air through the conduit MB to the forward end of the cylinder I30. This withdraws the rods I26 and (26a. from the sand hoppers I20 and I2fla. The valve (H2 is next opened to admit air through the conduit M2 to the forward end of the cylinder 56. This lowers the track sections 53 and 53a and disengages the flasks 8 and 4 from the carriages I6 and Hill. The valve 3 is closed and the valve 3IIa is opened to admit air through the conduit lIIa to the rearward end of the cylinder 35. This withdraws the carriages I6 and Ilia to their starting position.

While the carriages I6 and Ilia are returning to their rearward position, the valves 320 and 3I9 are opened for admitting air through the conduits 428 and M9 to the rearward end of the cylinder I73 and the rearward end of the cylinder I53, respectively. The downward actuation of the cylinder I'IE deposits the cope mold 6 on a drag flask on the conveyor 3. The actuation of the cylinder I53 pivots the turnover frame I44 to a position to receive the drag flask 4. The valve MI is now actuated for admitting air through the conduit lZI to the forward end of the cylinder I lI. This causes the turnover frame I l l to clasp the drag flask G. The valve 320 is closed and the valve 32% opened for admitting air through the conduit 250. to the forward end of the cylinder H3. This actuation of the cylinder I'iB raises the cope flask hoist ready to receive another flask. The valve 322 is now opened admitting air through the conduit 422 to the rearward end of the cylinder It l. This forces the rods i6!) forward one step. The valve 322 is now closed and the valve 322a opened to admit air through the conduit i22a to the forward end of the cylinder its for withdrawing the rods Hill to their normal position. While the rods IEO are returning, the valve 318 is closed and the valve 3I9a is opened to admit air by means of the conduit disc to the forward end of the cylinder I53.

This pivots the turnover frame IM to deposit the drag flask d on the conveyor 3. As soon as the drag flask d has been deposited on the conveyor 3, the valve 32i is closed and the valve arm is opened to admit air through the conduit saw to v the rearward end or the cylinder i l'I. This causes the turnover frame I44 to release the flask 4.

Also while the carriages I5 and IM are returning to their rearward positions, the valve 3I0 is closed and the valve Ema is opened to admit air through the conduit Him to the rearward end 'of the cylinder $30. This forces the rods I23 and 2651 back through the hoppers I20 and little.

It will be understood that some of the separate steps described can be timed to be carried out simultaneously. This overlapping of steps which do not conflict with each other is substantially essential since the entire cycle which I have described can be completed by my machine in from 20 to 45 seconds, depending upon the desired rate of production. The exact length of the cycle will depend upon the speed of the motor 395. Preferably this motor 356 is of the variable speed type whereby the cycle length may be changed as desired.

Ihave described a machine capable of carrying out a complete mold making cycle. This machine simultaneously places a cope flask and a drag flask into a cope mold making station and a drag mold making station. These flasks are simultaneously seated upon their respective pattern plates and a pair of strike offs is placed over each of these flasks. Liquid parting is applied to the pattern plates as the strike ofis move into position. Sand is then simultaneously released from a substantial height into each of these flasks and this sand is immediately initially struck off. Tamping heads are then lowered upon the sand and the flask and pattern plate joggled from beneath against the tamping heads. The

tamping heads are then removed and another strike off actuated to level the sand with the top of the flask. The cope flask and drag flask are then removed from the mold making stations and simultaneously empty flasks are placed in the stations to replace them. The subcycle of making a mold consisting of placing the strike offs, dropping the sand, and tamping the sand may then be immediately repeated. While this cycle is being repeated, the drag flask is inverted and placed upon a conveyor. By means of this conveyor it is transported to a point where it is mated with a cope flask, and the resulting mold is removed from the machine automatically ready for pouring. Thus, it is seen that my machine involves not only a rapid, complete and automatic cycle but it also involves a subcycle for making the molds. By designing a machine in which the over-all cycle of making a complete mold is dividedinto at least two subcycles consisting (1) of the preparing of the individual mold halves and (2) of inverting one of the mold halves and mating them together to form the completed mold, which subcycles may each be carried on simultaneously, I have provided an entirely automatic machine capable of exceedingly rapid operation. By this telescoping of the operating cycles and by complete automatic coordination of the mold making operations at both the cope mold making station and the drag moldmaking station, I am able to provide an automatic mold making machine which is compact and, despite the large number of separate steps carried out by the machine, is relatively simple.

It is recognized that many modifications of my machine may be made, each of which will not affect the principle of my invention. Each of these modifications is to be considered as included in the hereinafter appended claims unless these claims by their language expressly provide otherwise.

I claim:

1. In an automatic mold making machine, the combination comprising: a step by step powered mold conveyor; a drag flask conveyor connecting with and terminating at said mold conveyor; means for moving flasks, step by step, along said drag flask conveyor toward said mold conveyor; a drag mold making station; said drag flask conveyor extending through said drag mold making station; a vertically reciprocable pattern plate within said drag flask conveyor at said drag mold making station; a cope flask conveyor connecting with and terminating at said mold conveyor; a cope mold making station; said cope flask conveyor extending through said cope mold making station; a vertically reciprocable pattern plate within said cope flask conveyor at said cope mold making station; a pair of primary strike offs, one

18 at said drag mold making station and one at said cope mold making station; means for simultaneously aligning each of said primary strike ofis with one of said pattern plates and for displacing them to one side of said pattern plates; apair of secondary strike offs, one at said drag mold making station and one at said cope mold making station; means for simultaneously aligning each of said secondary strike offs with one of said pattern plates and for displacing them to one side of each of said pattern plates; a pair of tamper heads, one at said drag mold making station and one at said cope mold making station; means for simultaneously aligning each of said tamper heads with one of said pattern plates and for displacing each of said tamper heads to one side of each of said pattern plates; a pair of stationary sand hoppers, each vertically aligned with and spaced a substantial distance above one of said pattern plates; means for effecting the simultaneous release of sand from each of said sand hoppers while said tamper heads are displaced to one side of said pattern plates; a turnover frame adjacent said drag mold making station; means on said turnover frame for clasping a drag flask; means adjacent said cope mold making station for placing a cope'mold on a drag mold while said drag mold is seated on said mold conveyor; means including a timing mechanism operatively connected to each of said elements of said mold making machine for coordinating the movement of each of said elements of said mold making machine.

2. In an automatic mold making machine, the combination comprising: a drag mold making station; a cope mold making station; a frame common to both of said stations; a pair of strike off frames mounted on said frame for horizontal reciprocating movement, one of said strike oif frames at each of said mold making stations; a pair of tamper heads mounted on said frame for horizontal reciprocating movement, one of said tamper heads at each of said mold making stations; vertically reciprocable means atv each of said mold making stations for supporting a pattern plate; a stationary sand hopper spaced a substantial distance above each of said pattern plates; means for releasing sand from each of said sand hoppers; a mold conveyor; a pair of flask conveyors; one of said flask conveyors passing through each of said mold making stations; each of said flask conveyors connecting with and terminating at said mold conveyor; a drag flask inverter frame, said inverter frame in one position being seated over the one of said conveyors passing through said drag mold making station and in another position seated over said mold conveyor; hoist means adjacent said cope mold making station and disposed over said mold conveyor for placing cope flasks on said mold conveyor; means for alternately, vertically aligning each of said strike offs with one of said vertically reciprocable means and displacing them to one side of said vertically reciprocable means; means for alternately vertically aligning each of said tamper heads with one of said vertically reciprocable means and displacing them to one side of said means; means for operating the said sand release means for each of said sand hoppers; means for reciprocating said turnover frame 'between said flask conveyor passing through said 3. In an automatic mold making machine, the combination comprising: a drag mold making station; a cope mold making station; a frame common to both of said stations; a pair of strike ofi frames mounted on said frame for horizontal reciprocating movement, one of said strike oil frames at each of said mold making stations; a pair of tamper heads mounted on said frame for horizontal reciprocating movement, one of said tamper heads at each of said mold making stations; vertically reciprocable means at each of said mold making stations for supporting a pattern plate; a stationary sand hopper spaced a substantial distance above each of said pattern plates; means for releasing sand from each of said sand hoppers; a mold conveyor, said mold conveyor having a track assembly and means movable therealong for intermittently, unidirectionally moving molds; a pairof flask conveyors each of said conveyors having a track assembly and means movable therealong for intermittently, unidirectionally moving flasks; one of said flask conveyors passing through each of said mold making stations; each of said flask conveyors connecting with and terminating at said mold conveyor; a drag flask inverter frame, said inverter frame in one position being seated over the one of said conveyors passing through said drag mold making station and in another position seated over said mold conveyor; hoist means adjacent said cope mold making station and disposed over said mold conveyor for placing cope flasks on said mold conveyor; means for alternately, vertically aligning each of said strike ofis with one of said vertically reciprocable means and displacing them to one side of said vertically reciprocable means; means for alternately vertically aligning each of said tamper heads with one of said vertically reciprocable means and displacing them to one side of said means; means for operating the said sand release means for each of said sand hoppers; means for re ciprocating said turnover frame between said flask conveyor passing through said drag mold making station and said mold conveyor; means for operating said hoist; and a timer for coordinating the operation of each of the aforesaid elements.

References Cited in the file of this patent UNITED STATES PATENTS Number Name Date 1,512,721 Sutton Oct. 21, 1924 2,325,501 Gedris July 2'7, 1943 

